DNA: Structure & Function (AQA AS Biology): Revision Note

Exam code: 7401

Written by: Lára Marie McIvor

Reviewed by: Cara Head

Updated on 14 July 2025

DNA: structure & function

Deoxyribonucleic acid (DNA) is a type of nucleic acid and forms a polynucleotide – it is made up of many nucleotides linked together in a chain

Nucleic acids

DNA is a polynucleotide, this means it is made up of many nucleotides bonded together in a long chain

Diagram of a DNA nucleotide showing a phosphate group, pentose sugar (deoxyribose), and nitrogenous base (A, C, G, T). — **A DNA nucleotide**

DNA molecule structure

DNA consists of two polynucleotide strands that run in opposite directions — this arrangement is called antiparallel
Each strand has a sugar-phosphate backbone, formed by alternating deoxyribose sugars and phosphate groups joined by phosphodiester bonds
Phosphodiester bonds connect as follows:
- The 5th carbon of one deoxyribose sugar bonds to the phosphate group
- Then that phosphate group bonds to the 3rd carbon of the next sugar in the chain
Each strand has a 3’ end and a 5’ end, based on which carbon on the sugar is free for bonding
One DNA strand runs from 5’ to 3’, and the other runs from 3’ to 5’, making the two strands antiparallel
The nitrogenous bases of each nucleotide project out from the backbone towards the interior of the double-stranded DNA molecule

Diagram of nucleotide structure showing phosphate group, pentose sugar, and nitrogenous bases: thymine, guanine, and adenine with bonds labelled. — **A single DNA polynucleotide strand showing the positioning of the ester bonds**

Hydrogen bonding

The two antiparallel DNA polynucleotide strands that make up the DNA molecule are held together by hydrogen bonds between the nitrogenous bases
These hydrogen bonds always occur between the same pairs of bases:
- Adenine (A) always pairs with thymine (T) – two hydrogen bonds are formed between these bases
- Guanine (G) always pairs with cytosine (C) – three hydrogen bonds are formed between these bases
- This is known as complementary base pairing
- These pairs are known as DNA base pairs

Diagram of DNA structure showing sugar-phosphate backbone and bases: thymine-adenine (2 bonds) and cytosine-guanine (3 bonds), with single nucleotide marked. — **A section of DNA – two antiparallel DNA polynucleotide strands held together by hydrogen bonds**

Double helix

DNA is not two-dimensional as seen in the diagram above
DNA is described as a double helix
This refers to the three-dimensional shape that DNA molecules form

Examiner Tips and Tricks

Be able to identify and label the components of a DNA molecule:

Sugar-phosphate backbone
Nucleotides
Complementary base pairs (A=T, C≡G)
Phosphodiester bonds (between nucleotides)
Hydrogen bonds (between bases)

You may be asked to calculate base numbers using base pairing rules if given the quantity of one base.

DNA function

Deoxyribonucleic acid (DNA) is an important information-carrying molecule
The function of DNA is to hold or store genetic information
DNA is the molecule that contains the instructions for the growth and development of all organisms

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Previous:Nucleotide Structure & the Phosphodiester BondNext:RNA: Structure & Function

DNA: Structure & Function (AQA AS Biology): Revision Note

DNA: structure & function

Nucleic acids

DNA molecule structure

Hydrogen bonding

Double helix

DNA function

Unlock more, it's free!

Join the 100,000+ Students that ❤️ Save My Exams

Biological Molecules

Biological Molecules: Carbohydrates

Biological Molecules: Key Terms

Biological Molecules: Reactions

Monosaccharides

Glucose

The Glycosidic Bond

Chromatography: Monosaccharides

Disaccharides

Starch & Glycogen

Cellulose

Biochemical Tests: Sugars & Starch

Finding the Concentration of Glucose

Biological Molecules: Lipids

Lipids

Phospholipids

Biochemical Tests: Lipids

Biological Molecules: Proteins

Amino Acids & the Peptide Bond

Chromatography: Amino Acids

Protein Structure & Function

Protein Interactions

Biochemical Tests: Proteins

Proteins: Enzymes

Many Proteins are Enzymes

Enzyme Specificity

How Enzymes Work

Required Practical: Measuring Enzyme Activity

Drawing a Graph for Enzyme Rate Experiments

Using a Tangent to Find Initial Rate of Reaction

Limiting Factors Affecting Enzymes: Temperature

Limiting Factors Affecting Enzymes: pH

Limiting Factors Affecting Enzymes: Enzyme Concentration

Limiting Factors Affecting Enzymes: Substrate Concentration

Limiting Factors Affecting Enzymes: Inhibitors

Control of Variables & Uncertainty

Nucleic Acids: Structure & DNA Replication

Nucleotide Structure & the Phosphodiester Bond

DNA: Structure & Function

RNA: Structure & Function

Ribosomes

The Origins of Research on the Genetic Code

The Process of Semi-Conservative Replication

Calculating the Frequency of Nucleotide Bases

The Watson Crick Model

ATP, Water & Inorganic Ions

The Structure of ATP

Hydrolysis & Synthesis of ATP

The Properties of Water

Inorganic Ions

Cell Structure

Cell Structure

The Cell Theory

Structure of Eukaryotic Cells

Specialisation of Eukaryotic Cells

Eukaryotic Cell Organisation

Structure of Prokaryotic Cells

Prokaryotic v Eukaryotic Cells

Viruses

The Microscope in Cell Studies

Methods of studying cells

Microscopy & Drawing Scientific Diagrams

Magnification Calculations

Cell Fractionation & Ultracentrifugation

Cell Division in Eukaryotic & Prokaryotic Cells

The Cell Cycle & Interphase

The Stages of Mitosis

Cytokinesis

Required Practical: Identifying Mitotic Stages

Investigating Plant Root Tips

Uncontrolled Cell Division & Cancer